JP2021074069A - Absorbent article - Google Patents

Abstract

To provide an absorbent article which is excellent in fitness in a back of a gluteal cleft part and wearing feeling.SOLUTION: An absorbent article includes a body including a surface sheet, an absorber, and a back surface sheet and a linear body compressed groove formed on a surface sheet side of the body, and has a longitudinal direction corresponding to a front-back direction of a wearer and a lateral direction perpendicular to the longitudinal direction. The body is sectioned into a front region, an intermediate region, and a back region in the longitudinal direction. The body compressed groove extends at least from the intermediate region to the back region. The absorber includes a longitudinal groove part which is provided in a central part in the lateral direction in the back region and extends in the longitudinal direction. The absorbent article further includes a rising suppression part arranged in a position separated backward from a back end part of the body compressed groove and on the longitudinal groove part. The rising suppression part has a non-compressed region provided on the surface sheet and the absorber and a compressed region arranged on both sides in the longitudinal direction and on both sides in the lateral direction of the non-compressed region.SELECTED DRAWING: Figure 1

Description

The present invention relates to absorbent articles such as sanitary napkins.

Patent Document 1 describes an absorbent article having an absorbent core and a plurality of grooves in which the rear core portion of the absorbent core extends in the vertical direction. In this absorbent article, the thick vertical groove portion located at the central portion in the width direction of the rear core portion makes it easy for the central portion in the width direction to protrude in the skin direction along the intergluteal cleft.

Patent No. 6567027

On the other hand, behind the intergluteal cleft (dorsal side), there is a substantially flat region where the sacrum and the like are located. In the absorbent article described in Patent Document 1, the fit and the feeling of wearing so as to follow a substantially flat region behind the intergluteal cleft were not considered.

An object of the present invention relates to the provision of an absorbent article having a good fit and wearing feeling behind the intergluteal cleft.

The absorbent article according to one embodiment of the present invention includes a main body including a front surface sheet, an absorber and a back surface sheet, and a linear main body pressing groove formed on the front surface sheet side of the main body, and is provided in front of and behind the wearer. It has a vertical direction corresponding to a direction and a horizontal direction orthogonal to the vertical direction.
The main body is divided into a front region, an intermediate region, and a rear region along the vertical direction.
The body squeeze groove extends from at least the intermediate region to the posterior region.
The absorber has a longitudinally extending flutes provided in the laterally central portion of the rear region.
The absorbent article further includes an upright restraining portion arranged on the vertical groove portion at a position rearward from the rear end portion of the main body pressing groove.
The standing restraint portion has a non-squeezed region and a squeezed region provided for the surface sheet and the absorber.
The squeezed area is arranged on both sides of the non-squeezed area in the longitudinal direction and on both sides in the lateral direction.

As described above, according to the absorbent article of the present invention, since the standing restraint portion is arranged on the vertical groove portion behind the main body pressing groove, the standing up by the vertical groove portion behind the intergluteal cleft is suppressed, and the intergluteal cleft It is possible to improve the fit and wearing feeling in the rear.

It is a top view which shows the absorbent article which concerns on one Embodiment of this invention. It is sectional drawing which cut at the line II-II of FIG. It is an enlarged view of the main part of FIG.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[Overall composition of napkin]
The absorbent article 1 shown in FIG. 1 includes a main body M, a pair of wing portions W, a pair of rear flap portions F, and a main body pressing groove 6. The absorbent article 1 is configured as a sanitary napkin and is hereinafter referred to as a napkin 1.
The napkin 1 has a vertical direction X corresponding to the front-rear direction of the wearer and a horizontal direction Y corresponding to the left-right direction of the wearer and orthogonal to the vertical direction X. Further, the napkin 1 has a thickness direction Z orthogonal to both the vertical direction X and the horizontal direction Y. In the present specification, with respect to the thickness direction Z, the side closer to the wearer's skin may be referred to as the upper or skin side, and the side closer to the clothing may be referred to as the lower or non-skin side when worn. The napkin 1 is preferably used at bedtime and may have a length of, for example, 30 cm or more along the vertical direction X.

The main body M extends along the vertical direction X and is fixed to the inner surface of the wearer's clothing when worn. The main body M has an absorber 4 described later, and has a function of absorbing a liquid substance (hereinafter, also referred to as “liquid”) such as menstrual blood of the wearer.

The main body M is divided into a front region M1, an intermediate region M2, and a rear region M3 along the vertical direction X.
The intermediate region M2 is a region facing the wearer's excretory portion when worn. In FIG. 1, the intermediate region M2 is a region between the front and rear base ends of the wing portion W in the main body M.
The anterior region M1 is an region arranged in front of the intermediate region M2 (ventral side of the wearer), and is arranged so as to face the front of the excretory portion of the wearer when worn.
The posterior region M3 is an region arranged behind the intermediate region M2 (dorsal side of the wearer), and is arranged so as to face the rear of the excretory portion of the wearer when worn.
The term “wearing” as used herein means a state in which the normal proper wearing position (the assumed wearing position of the napkin 1) is maintained, and does not include the case where the napkin 1 is in a state deviated from the wearing position.
When the napkin 1 does not have the wing portion W, the main body M is divided into three equal parts along the vertical direction X, the central region is set as the intermediate region M2, and the region arranged in front of the intermediate region M2 is the front region. The area arranged behind M1 is referred to as a rear area M3.

The wing portion W is configured so as to largely protrude outward in the lateral direction Y from the intermediate region M2 of the main body M.
The rear flap portion F is configured to bulge outward in the lateral direction Y in the rear region M3 of the main body M.
The napkin 1 does not have to have at least one of the wing portion W and the rear flap portion F.

As shown in FIG. 2, the napkin 1 includes an absorber 4, a front surface sheet 2, a back surface sheet 3, and a pair of side sheets 5. In the main body M, the napkin 1 has a structure in which the back surface sheet 3, the absorber 4, and the front surface sheet 2 are laminated in the thickness direction Z. These configurations are appropriately joined and integrated by, for example, joining with an adhesive, a heat seal, or the like, embossing with the main body pressing groove 6.

The absorber 4 extends along the vertical direction X and is arranged between the front surface sheet 2 and the back surface sheet 3. The absorber 4 absorbs the liquid from the surface on the surface sheet 2 side and diffuses it inside to hold the liquid.
The absorber 4 has an absorbent core 7 and a core wrap sheet 8.
The absorbent core 7 may be formed of, for example, a fiber aggregate composed of hydrophilic fibers such as pulp fibers, or may have a structure in which the fiber aggregate retains a water-absorbent polymer. ..
The core wrap sheet 8 has a function of covering the absorbent core 7 and maintaining the shape of the absorbent core 7, for example. The core wrap sheet 8 is formed of, for example, tissue paper-like thin and soft paper, a liquid-permeable non-woven fabric, or the like.

The surface sheet 2 is configured as a liquid-permeable sheet material, and is arranged above the thickness direction Z of the absorber 4. Between the surface sheet 2 and the absorber 4, the permeability of the liquid from the surface sheet 2 to the absorber 4 is improved, the liquid absorbed by the absorber 4 is prevented from returning to the surface sheet 2, and the like. From the viewpoint of, a second sheet (sublayer sheet) may be arranged.

The back sheet 3 is arranged below the thickness direction Z of the absorber 4. The back surface sheet 3 is joined to the front surface sheet 2 and the side sheet 5 by a heat seal, for example, at the periphery thereof, without the intervention of the absorber 4. As a result, a heat seal portion S (see FIG. 1) is formed on the peripheral edge of the napkin 1. The back sheet 3 may be bonded to the absorber 4 with an adhesive or the like.
The back surface sheet 3 is formed of, for example, a sheet material having functions such as poor liquid permeability, water vapor permeability, and water repellency. As the sheet material, for example, a film made of a thermoplastic resin, a laminate of the film and a non-woven fabric, or the like can be used.
Although not shown, the back sheet 3 is provided with an adhesive portion for fixing the main body M, the wing portion W, and the like to the clothes.

The pair of side sheets 5 are arranged on the lateral Y outer side of the surface sheet 2. As the material of the side sheet 5, a sheet material having a lower hydrophilicity than the surface sheet 2 is preferable, and specifically, a non-woven fabric having a lower hydrophilicity than the surface sheet 2, a film material, and a laminated structure of the non-woven fabric and the film material. The sheet can be mentioned. The side sheet 5 is joined to the surface sheet 2 by, for example, an adhesive E.

[Overall composition of the main body squeezing groove]
As shown in FIGS. 1 and 2, a linear main body pressing groove 6 is formed on the surface sheet 2 side of the main body M. The "linearity" in the squeezing groove is not limited to a linear aspect in a plan view, and includes a curved aspect and an aspect including a linear shape and a curved shape. Further, this "linear" also includes an embodiment in which the high-pressure squeezed portions are lined up slightly separated in the extending direction, and a linear groove is formed as a whole.

The main body pressing groove 6 is formed by pressing the main body M from the surface sheet 2 side of the main body M in the thickness direction Z.
As shown in FIG. 2, the main body pressing groove 6 has a configuration in which the front surface sheet 2 and the absorber 4 are integrally recessed toward the back surface sheet 3 side. The main body pressing groove 6 can be formed according to a conventional method by pressing processing such as heat embossing processing or ultrasonic sealing processing. In the main body pressing groove 6, the surface sheet 2 and the absorber 4 are integrated by heat fusion or the like.

With such a configuration, the main body pressing groove 6 has a higher rigidity than other regions and is a portion that is not easily deformed. Therefore, when the napkin 1 receives a force, the main body pressing groove 6 can function as a deformation starting point that promotes deformation of the surrounding low-rigidity region and a portion that exerts a drag force against the force.

As shown in FIG. 1, the main body squeezing groove 6 extends from at least the intermediate region M2 to the rear region M3. In the example shown in FIG. 1, the main body squeezing groove 6 extends from the front region M1 through the intermediate region M2 to the rear region M3.
More specifically, in the main body squeezing groove 6, left and right paired squeezing grooves extend in the vertical direction X in the intermediate region M2, and these paired squeezing grooves extend in the lateral direction Y in the front region M1 and the rear region M3. Extends toward each other so that they are closely connected to each other.
The phrase "extending in the vertical direction X" in the main body pressing groove 6 is not limited to the mode in which the main body pressing groove 6 extends parallel to the vertical direction X, and the main body pressing groove 6 includes a vector component parallel to the vertical direction X as a whole. It may extend in the direction and may include, for example, a constriction.
The phrase "extending inward in the lateral direction Y" of the main body pressing groove 6 is not limited to a mode in which the main body pressing groove 6 extends parallel to the lateral direction Y, and extends in a direction including a vector component in the lateral direction Y. Just do it. In the example shown in FIG. 1, the main body pressing groove 6 is formed in a curved shape extending inward in the horizontal direction Y and extending outward in the vertical direction X in the front region M1 and the rear region M3.

In other words, the main body pressing groove 6 is formed in an annular shape surrounding the central portion of the lateral Y in the intermediate region M2 of the main body M. However, the main body pressing groove 6 is not limited to the mode in which the entire body is continuously formed, and may be formed intermittently with a break portion.
With this configuration, the rear end portion 6b located at the rearmost portion of the main body pressing groove 6 becomes the tip of the convex portion protruding rearward. The rear end portion 6b is arranged, for example, on the vertical groove portion 9 described later.
The napkin 1 may have a rear squeezing groove 17 extending in the lateral direction Y, an inner squeezing groove 18, and the like as linear squeezing grooves other than the main body squeezing groove 6. These configurations will be described later.

[Structure of grooves formed in the absorber (absorbent core)]
As shown in FIG. 1, the absorber 4 has a vertical groove portion 9 extending in the vertical direction X provided at the central portion in the horizontal direction in the rear region M3. The lateral central portion in the rear region M3 means the central region when the napkin 1 is divided into three equal parts in the lateral direction Y. The vertical groove portion 9 is preferably arranged on the vertical center line CL that bisects the napkin 1 in the horizontal direction Y.
The term "extending in the vertical direction X" in the vertical groove portion 9 means that it may extend in the vertical direction X as a whole, and includes a mode in which at least a part of the vertical groove portion 9 is curved or meandering.
The flutes 9 may be provided at least in the rear region M3, but as shown in FIG. 2, the flutes 9 may extend to the intermediate region M2 and may further extend to the front region M1. Further, the vertical groove portion 9 may be provided over the entire length of the absorbent core 7 in the vertical direction X.

As shown in FIG. 2, the vertical groove portion 9 includes, for example, a groove formed downward from the upper surface of the absorbent core 7 in the thickness direction Z. The flutes 9 are preferably configured with a basis weight lower than that of the surrounding area.
The "low basis weight" of the flutes 9 is a concept including a form in which the material of the absorbent core 7 is present and a form in which the material of the absorbent core 7 is not present. In the form in which the material of the absorbent core 7 is present in the flutes 9, the block-shaped portions of the absorbent cores 7 located on both sides of the flutes 9 are connected to each other, so that the absorbent cores 7 are deformed and destroyed. It is more preferable because flexibility can be imparted while suppressing such factors.
The vertical groove portion 9 is not limited to the above-described configuration, and may be a groove formed upward from the lower surface in the thickness direction Z.

As shown in FIG. 2, the absorbent core 7 may have other vertical groove portions 10 arranged on both sides of the vertical groove portion 9 in the lateral direction Y. Further, although not shown, the absorbent core 7 may have a plurality of lateral grooves extending in the lateral direction Y. The absorbent core 7 may be divided into blocks by the vertical groove portions 9 and 10 and the horizontal groove portions.

Since the vertical groove portion 9 is formed thinner than the surroundings, the bending rigidity from the lateral direction Y is low. Therefore, when the rear region M3 receives an external force in the lateral direction Y from the left and right buttocks of the wearer, the vertical groove portion 9 becomes the starting point of deformation, and it becomes easy to stand up on the skin side so as to enter the intergluteal cleft of the wearer. .. More specifically, the side wall portion is bent so as to face both the left and right sides starting from the bottom portion of the vertical groove portion 9, and the center of the bottom portion of the vertical groove portion 9 tends to protrude upward. As a result, it is possible to prevent a gap from being formed between the rear region M3 in which the vertical groove portion 9 is formed and the intergluteal cleft of the wearer, and it is possible to improve the fit in the rear region M3. Therefore, the napkin 1 can effectively prevent liquid leakage to the rear even in the sleeping posture.
On the other hand, the wearer's body shape has a relatively flat region such as the sacrum located behind the intergluteal cleft. Therefore, in the present embodiment, as described below, the standing suppressing portion 12 is provided in the region behind the main body pressing groove 6 to suppress the standing of the vertical groove portion 9 behind the intergluteal cleft.

[Basic configuration of the standing restraint unit]
As shown in FIG. 1, the napkin 1 includes an upright suppressing portion 12 arranged on the vertical groove portion 9 at a position separated rearward from the rear end portion 6b of the main body pressing groove 6. The standing restraining portion 12 is formed by squeezing as described later, but is formed independently of the linear squeezing groove such as the main body squeezing groove 6. Since the standing suppressing portion 12 is formed on the absorber 4, it is located in front of the heat sealing portion S formed on the peripheral edge of the main body M.

As shown in the enlarged view of FIG. 3, the standing restraint portion 12 has a non-squeezed region 13 and a squeezed region 14 provided for the surface sheet 2 and the absorber 4. The compressed region 14 is arranged on both sides of the non-compressed region 13 in the vertical direction X and the horizontal direction Y. The standing suppression unit 12 is configured as an aggregate of the non-squeezed region 13 and the compressed region 14, and in the example of FIG. 3, it is composed of the non-squeezed region 13 and four compressed regions 14 arranged around the non-squeezed region 13. .. Further, in FIG. 3, for the sake of explanation, the squeezed region 14 is shown by hatching with diagonal lines.

Similar to the main body pressing groove 6, the pressing region 14 has a configuration in which the front surface sheet 2 and the absorber 4 are integrally recessed toward the back surface sheet 3 side. The squeezed region 14 is formed by subjecting the surface sheet 2 and the absorber 4 to a heat embossing process or a squeezing process such as an ultrasonic seal. As a result, the squeezed region 14 has a higher fiber density than the surrounding region, and thus has a higher rigidity.

The compressed region 14 includes two first compressed regions 14a arranged on both sides of the non-compressed region 13 in the vertical direction X and two second compressed regions 14b arranged on both sides of the non-compressed region 13 in the horizontal direction Y. Including.
In the following description, when the first squeezed region 14a and the second squeezed region 14b are used without distinction, they are simply referred to as the squeezed region 14.

The planar shape of each squeezed region 14 as viewed from the thickness direction Z is not limited to a shape close to a trapezoidal shape with rounded corners as shown in the figure, and various shapes can be adopted. As the planar shape, for example, one type or two or more types selected from a circular shape, an elliptical shape, a polygonal shape, a drop shape, a shape similar to these, and other shapes can be selected. Further, each squeezed region 14 is not limited to the same shape, and may have a different shape.
In the example shown in FIG. 3, the plurality of squeezed regions 14 are arranged slightly apart from each other as shown in the figure. However, the present invention is not limited to this, and a plurality of squeezed regions 14 may be connected to each other.

The non-squeezed region 13 is a region in which the surface sheet 2 and the absorber 4 are not heat-embossed or squeezed by an ultrasonic seal or the like. As a result, the surface sheet 2 in the non-squeezed region 13 is located above the surface sheet 2 in the compressed region 14 in the thickness direction Z. That is, the non-squeezed region 13 is configured to swell upward from the squeezed region 14 in the thickness direction Z, and has a relatively soft feel. However, in the non-compressed region 13, the surface sheet 2 and the absorber 4 may be slightly compressed in the thickness direction Z as the compressed region 14 is compressed. That is, the upper surface of the non-squeezed region 13 is downward from any of the squeezing grooves such as the standing restraining portion 12 and the main body squeezing groove 6 in the main body M as compared with the upper surface of the region separated by, for example, 5 mm or more on the XY plane. It may be located in.

The standing suppressing portion 12 is arranged on the vertical groove portion 9. "The standing restraining portion 12 is arranged on the vertical groove portion 9" means that the center point CP of the standing suppressing portion 12 in the vertical direction X and the horizontal direction Y is the vertical groove portion 9 in a plan view seen from the thickness direction Z. It means that it is placed at a position that overlaps with the bottom. The "center point CP in the vertical direction X and the horizontal direction Y of the standing suppression unit 12" is the center line when the standing suppressing unit 12 is bisected in the vertical direction X and the center line when the standing suppressing unit 12 is bisected in the horizontal direction Y. Means the position where In FIG. 3, the center point CP is indicated by dots for the sake of explanation.
For example, at least a part of the first squeezed region 14a and the non-squeezed region 13 may overlap with the bottom portion of the vertical groove portion 9 in the plan view. Alternatively, in addition to at least a part of the first squeezed region 14a and the non-squeezed region 13, at least a part of the second squeezed region 14b may also overlap the bottom of the flutes 9 in the plan view.

As described above, the vertical groove portion 9 receives an external force in the lateral direction Y from the left and right buttocks of the wearer, and easily stands up toward the skin side toward the wearer's intergluteal cleft. In addition, by providing the standing restraint portion 12 in the region behind the buttocks, the bending rigidity of the vertical groove portion 9 in the region is locally increased, and the standing deformation in the region is suppressed.
Specifically, a plurality of high-rigidity regions arranged in the vertical direction X can be provided on the vertical groove portion 9 by the squeezing regions 14 (first squeezing regions 14a) on both sides of the non-squeezing region 13 in the vertical direction X. In addition to this, the squeezed regions 14 (second squeezed regions 14b) on both sides of the lateral Y of the non-squeezed regions 13 can provide high-rigidity regions on the left and right side wall portions of the flutes 9 and / or in the vicinity thereof. .. Further, by arranging the plurality of compressed regions 14 around the non-compressed region 13, a plurality of high-rigidity regions are provided in close proximity to each other.
As a result, in the standing suppressing portion 12, the bending rigidity is increased from the bottom portion of the vertical groove portion 9 to the vicinity of the side wall portion. Therefore, the standing restraining unit 12 satisfactorily exerts drag against the stress from the lateral direction Y caused by the standing deformation of the region facing the intergluteal cleft. That is, the standing suppressing portion 12 can suppress deformation such that the side wall portion bends from the bottom portion of the vertical groove portion 9 to the left and right sides, and a substantially flat state can be easily maintained.
That is, in addition to the napkin 1 having the above configuration standing upright and fitting to the skin side by the flutes 9 with respect to the wearer's intergluteal cleft, the napkin 1 has a relatively flat region behind the intergluteal cleft. , The standing restraint portion 12 suppresses the standing up and fits. Therefore, in the napkin 1, not only in the intergluteal cleft, but also in the region behind the intergluteal cleft, the generation of a gap with the wearer can be prevented, and in particular, the leakage of the liquid to the rear in the sleeping posture can be prevented.
Further, since the non-squeezed region 13 of the standing suppression portion 12 is not squeezed, it has a softer feel than the squeezed region 14. As a result, it is suppressed that the entire standing suppressing portion 12 has a hard feel. Therefore, it is possible to prevent the standing suppressing portion 12 from giving a hard and unpleasant feeling to the wearer, and it is possible to give a good wearing feeling to the wearer.

[Dimensions of the standing restraint part]
The dimension D1 of the standing restraint portion 12 in the lateral direction Y is preferably larger than the groove width D3 of the vertical groove portion 9 in the lateral direction Y. The dimension D1 in the lateral direction Y of the standing restraining portion 12 means the largest dimension among the dimensions of the standing suppressing portion 12 in the lateral direction Y.
In this configuration, the side wall portion of the vertical groove portion 9 is squeezed by the squeezing region 14, and deformation from the bottom portion of the vertical groove portion 9 to the side wall portion is more reliably suppressed. Therefore, the standing restraint portion 12 can more reliably suppress the standing deformation of the vertical groove portion 9 behind the intergluteal cleft.

Further, the dimension D1 of the standing restraining portion 12 in the lateral direction Y is preferably equal to or larger than the dimension D2 of the standing suppressing portion 12 in the vertical direction X. That is, the standing suppressing portion 12 may have an isotropic shape with respect to the vertical direction X and the horizontal direction Y, or may have a flat shape in the horizontal direction Y. The dimension D2 in the vertical direction X of the standing restraining portion 12 means the largest dimension among the dimensions of the standing suppressing portion 12 in the vertical direction X.
In this configuration, the high-rigidity region is arranged long in the lateral direction Y in the standing suppression unit 12. As a result, the squeezed region 14 is likely to exert a sufficient drag force against a force from the outside in the lateral direction Y, and the standing deformation of the vertical groove portion 9 behind the intergluteal cleft can be more reliably suppressed.

The groove width D3 in the lateral direction Y of the vertical groove portion 9 is preferably 0.5 mm or more, more preferably 1 mm or more, preferably 10 mm or less, and more preferably 5 mm or less. The width of the vertical groove portion 9 is obtained by measuring the width at the opening of the vertical groove portion 9. For example, the opening width is measured by placing the absorbent core 7 horizontally and adjusting the measurement magnification with a microscope (VHX-1000 manufactured by KEYENCE) to enlarge the upper surface. Alternatively, the absorbent core 7 is cut with a feather single-edged razor, and the cross section of the cut sample is observed with a microscope (VEYENCE VHX-1000) at a magnification of 20 to 100 times. The groove width may be measured.
The dimension D1 in the lateral direction Y of the standing suppressing portion 12 is preferably 5 mm or more, more preferably 10 mm or more, preferably 25 mm or less, and more preferably 20 mm or less from the viewpoint of sufficiently covering the groove width D3. Is.
The dimension D2 in the vertical direction X of the standing restraint portion 12 is preferably 3 mm or more, more preferably 8 mm or more, and preferably 23 mm or less, from the viewpoint of having a dimension equal to or smaller than the dimension D1. It is preferably 18 mm or less.

[Detailed configuration of the standing restraint section]
As shown in FIG. 3, the squeezed region 14 preferably includes a high pressure squeezed portion 15 and a low pressure squeezed portion 16 that is squeezed weaker than the high pressure squeezed portion 15. In the squeezed region 14 of FIG. 3, the high-pressure squeezed portion 15 has a bottom surface deeper in the thickness direction Z than the low-pressure squeezed portion 16. That is, the surface sheet 2 in the high-pressure squeezing portion 15 is located below the surface sheet 2 in the low-pressure squeezing portion 16 in the thickness direction Z. In FIG. 3, the high-pressure squeezed portion 15 is indicated by high-density shaded hatching, and the low-pressure squeezed portion 16 is indicated by low-density shaded hatching.
Such a squeezing region 14 is an embossed roll including, for example, a convex portion for forming a low-pressure squeezed portion provided on an outer peripheral surface and a convex portion for forming a high-pressure squeezed portion further protruding from the convex portion for forming a low-pressure squeezed portion. Is formed using. Specifically, the laminated body including the surface sheet 2 and the absorber 4 and the like is integrally heated and pressurized between the embossed roll and the flat roll having a flat outer peripheral surface. As a result, the high-pressure squeezing portion 15 is formed in the region pressed by the high-pressure squeezing portion forming convex portion, and the low-pressure squeezing portion 16 is formed in the region pressed by the low-pressure squeezing portion forming convex portion.
The high-pressure squeezing portion 15 is squeezed by the convex portion for forming the high-pressure squeezing portion at a pressure higher than that of the low-pressure squeezing portion 16, so that the high-pressure squeezing portion 15 has a higher density than the low-pressure squeezing portion 16 and a higher rigidity than the low-pressure squeezing portion 16. Become a part.

In such a squeezed region 14, in addition to being able to sufficiently squeeze and increase the rigidity by the high-pressure squeezing portion 15, the low-pressure squeezing portion 16 can prevent the squeezed region 14 from feeling too hard. Therefore, such an upright restraining portion 12 can give the wearer a good fit and a feeling of wearing in the rear part of the buttocks.

The low pressure squeezing section 16 preferably includes a contour portion that borders the outer edge of the squeezing region 14. That is, in the standing suppression portion 12, at least a part of the contour portion is configured as the low pressure squeezing portion 16, and the high pressure squeezing portion 15 does not continuously form the contour portion. In the example shown in FIG. 3, the low-pressure squeezing portion 16 constitutes the entire contour portion of each squeezing region 14.
Since at least a part of the contour portion is composed of the low pressure squeezed portion 16, the feel of the squeezed region 14 is softer than that when the entire contour portion is composed of the high pressure squeezed portion. Therefore, such an upright restraining portion 12 can give a good wearing feeling to the wearer.

A plurality of high-pressure squeezing portions 15 in each squeezing region 14 are arranged in an island shape in, for example, the low-pressure squeezing portion 16. A plurality (for example, four) of the high-pressure squeezing portions 15 are arranged in the low-pressure squeezing portion 16 so as to be separated from each other. The planar shape of each high-pressure squeezing portion 15 as viewed from the thickness direction Z is, but is not limited to, a quadrangular shape with rounded corners in the example shown in FIG. The planar shape can be selected from, for example, one or two or more types selected from a circular shape, an elliptical shape, a polygonal shape, a shape similar thereto, and other shapes.

By arranging a plurality of high-pressure squeezing portions 15 in an island shape in the low-pressure squeezing portion 16, the rigidity inside the squeezing region 14 can be appropriately increased. Further, by adjusting the arrangement and the number of the high-pressure squeezing portions 15, it becomes easy to obtain the desired rigidity. Further, by providing the high-pressure squeezing portion 15 in addition to the contour portion of the squeezing region 14, it is possible to suppress the standing suppressing portion 12 from giving the wearer a hard and unpleasant feel, and it is possible to give the wearer a good wearing feeling. ..

The non-squeezed region 13 preferably includes the center point CP of the standing restraint portion 12 in the vertical direction X and the horizontal direction Y.
By providing the center point CP on the non-squeezed region 13 located inside the standing restraining portion 12, each of the squeezed regions 14 can be easily arranged symmetrically with respect to the vertical direction X and the horizontal direction Y. As a result, one squeezed region 14 is configured to be larger than the other squeezed region 14, and it is possible to prevent the hard squeezed region 14 from easily coming into contact with the skin. Therefore, it is possible to prevent the standing suppressing portion 12 from giving a hard feeling to the wearer, and it is possible to give a good wearing feeling to the wearer.

[Construction of rear squeezing groove]
As shown in FIG. 1, as described above, the napkin 1 further has a linear rear squeezing groove 17 arranged in the rear region M3 in addition to the main body squeezing groove 6.
The rear squeezing groove 17 is formed by squeezing the main body M from the surface sheet 2 side in the thickness direction Z in the same manner as the main body squeezing groove 6. Similar to the main body pressing groove 6, the rear pressing groove 17 has a configuration in which the front surface sheet 2 and the absorber 4 are integrally recessed toward the back surface sheet 3 side. The rear squeezing groove 17 can be formed according to a conventional method by squeezing such as heat embossing or ultrasonic sealing.

The rear squeezing groove 17 is arranged between the main body squeezing groove 6 and the standing restraining portion 12. The rear squeezing groove 17 extends in the lateral direction Y and is convex rearward, and neither the front end portion 17a nor the rear end portion 17b is arranged on the vertical groove portion 9. The rear squeezing groove 17 is formed in a curved shape extending from the right side region to the left side region of the main body M with the vertical center line CL in between.

The front end portion 17a of the rear squeezing groove 17 is a portion of the rear squeezing groove 17 located at the foremost position in the vertical direction X. In the example shown in FIG. 1, the front end portion 17a is configured as one end point 17c of the left and right end points 17c and 17d of the rear squeezing groove 17. In the example shown in FIG. 1, the front end portion 17a is separated from the main body pressing groove 6, but may be connected to the main body pressing groove 6. Further, the front end portion 17a may be located in front of the rear end portion 6b of the main body pressing groove 6.
Similarly, the rear end portion 17b of the rear squeezing groove 17 is the rearmost portion of the rear squeezing groove 17 in the longitudinal direction X. As described above, since the rear squeezing groove 17 is configured to be convex rearward, the rear end portion 17b is configured as the tip of the convex portion.

More specifically, the rear squeezing groove 17 extends from the end point 17c, which is the front end portion 17a, in a direction including a vector component outward in the vertical direction X and a vector component inward in the horizontal direction Y. Further, the rear squeezing groove 17 extends toward the rear end portion 17b across the vertical groove portion 9. Then, the rear squeezing groove 17 changes its direction with the rear end portion 17b as a boundary, and extends in a direction including a vector component toward the inside of the vertical direction X and the outward direction of the horizontal direction Y. In the example shown in FIG. 1, the portion of the rear squeezing groove 17 on the end point 17d side, which is different from the front end portion 17a, is formed in a spiral shape.

From a different point of view, the right side portion and the left side portion sandwiching the rear end portion 17b of the rear pressing groove 17 include vector components in the vertical direction X inward from the rear end portion 17b toward the respective end points 17c and 17d, respectively. .. As a result, when a force is applied from both sides in the lateral direction Y, the right side portion and the left side portion each receive the force and serve as a deformation starting point, so that the force in the direction of projecting the region on the rear end portion 17b upward. Works. As a result, the napkin 1 is prevented from standing on the flutes 9 separated from the rear end 17b. Therefore, the posterior squeezing groove 17 cooperates with the standing suppressing portion 12, and the standing on the vertical groove portion 9 behind the intergluteal cleft can be more reliably suppressed.

[Additional explanation of this embodiment]
Hereinafter, the description of this embodiment will be supplemented.

(Example of arrangement of standing restraint part)
The distance in the vertical direction X between the front end portion of the standing suppression portion 12 and the rear end portion 6b of the main body pressing groove 6 is determined by the standing suppressing portion 12 while arranging the standing suppressing portion 12 independently of the main body pressing groove 6. From the viewpoint of effectively obtaining the standing inhibitory action, it is preferably 20 mm or more, more preferably 25 mm or more, preferably 45 mm or less, and more preferably 40 mm or less.
The distance in the vertical direction X between the rear end portion of the standing restraining portion 12 and the rear end portion of the main body M is preferably 15 mm or more, more preferably from the viewpoint of facilitating the placement of the standing suppressing portion 12 behind the intergluteal cleft. Is 20 mm or more, preferably 50 mm or less, and more preferably 45 mm or less.

(Additional explanation of absorbent core)
As shown in FIG. 2, the absorbent core 7 has a high basis weight portion 11 located at the center portion in the lateral direction Y in the intermediate region M2 and having a basis weight higher than that of the surroundings. The high basis weight portion 11 projects, for example, upward in the thickness direction Z. The high basis weight portion 11 can enhance the absorbency of the absorbent core 7 in the intermediate region M2 and enhance the fit in the excretory portion of the wearer.

(Construction of other squeezing grooves)
As shown in FIG. 1, the napkin 1 may further include an inner pressing groove 18 arranged inside the annular structure of the main body pressing groove 6 in addition to the main body pressing groove 6 and the rear pressing groove 17. The inner squeezing groove 18 extends in the lateral direction Y, and in the example shown in FIG. 1, is formed to be convex outward in the vertical direction X. A plurality of inner pressing grooves 18 may be arranged, and in the example shown in FIG. 1, one is arranged in the front region M1 and two are arranged in the rear region M3. The convex portion of the inner pressing groove 18 is arranged on, for example, the vertical groove portion 9. In such an inner pressing groove 18, for example, the left and right portions sandwiching the convex portion receive forces from both sides in the lateral direction Y to serve as deformation starting points, and can promote the vertical groove portion 9 to stand upward.

Further, as shown in FIGS. 1 and 2, the napkin 1 may further include an intermediate squeezing groove 19 extending in the vertical direction X, which is arranged in the central portion of the intermediate region M2 in the lateral direction Y. The central portion of the intermediate region M2 in the lateral direction Y means the central region when the intermediate region M2 is divided into three equal parts in the lateral direction Y. The intermediate squeezing groove 19 is arranged on the high basis weight portion 11 of the absorbent core 7 in the present embodiment.
The intermediate squeezing grooves 19 are composed of fragments, and a plurality of intermediate squeezing grooves 19 (four in the illustrated example) are arranged so as to be separated from each other.
Since the starting point of deformation is added to the intermediate region M2 by the intermediate pressing groove 19, the intermediate region M2 is compressed in the lateral direction Y even when an external force in the lateral direction Y is applied to the intermediate region M2 from the wearer's legs or the like. It is possible to suppress such undesired deformation.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and it goes without saying that various modifications can be made without departing from the gist of the present invention.

In the above embodiments, examples of sanitary napkins have been shown as absorbent articles, but the present invention is not limited thereto. The absorbent article of the present invention may be, for example, a urine absorbing pad, a vaginal discharge sheet, a disposable diaper, or the like.

1 ... Napkin (absorbent article)
2 ... Front sheet 3 ... Back sheet 4 ... Absorber 6 ... Main body squeezing groove 9 ... Vertical groove 12 ... Standing suppression 13 ... Non-squeezing area 14 ... Squeezing area M1 ... Front area M2 ... Intermediate area M3 ... Rear area

Claims (8)

It is provided with a main body including a front surface sheet, an absorber and a back surface sheet, and a linear main body pressing groove formed on the front surface sheet side of the main body, and is orthogonal to the vertical direction corresponding to the front-back direction of the wearer and the vertical direction. It is an absorbent article having a lateral direction to be used.
The main body is divided into a front region, an intermediate region, and a rear region along the vertical direction.
The body squeeze groove extends from at least the intermediate region to the posterior region.
The absorber has a longitudinally extending flutes provided in the laterally central portion of the rear region.
The absorbent article is further provided with an upright restraining portion arranged on the vertical groove portion at a position rearward from the rear end portion of the main body pressing groove.
The standing restraining portion has a non-squeezed region and a squeezed region provided for the surface sheet and the absorber.
The squeezed area is an absorbent article arranged on both sides of the non-squeezed area in the longitudinal direction and both sides in the lateral direction. The absorbent article according to claim 1, wherein the dimension of the standing restraining portion in the lateral direction is larger than the groove width of the vertical groove portion in the lateral direction. The absorbent article according to claim 1 or 2, wherein the dimension of the standing restraining portion in the horizontal direction is equal to or larger than the dimension of the standing suppressing portion in the vertical direction. The absorbent article according to any one of claims 1 to 3, wherein the squeezed region includes a high-pressure squeezed portion and a low-pressure squeezed portion squeezed weaker than the high-pressure squeezed portion. The absorbent article according to claim 4, wherein the low-pressure squeezing portion includes a contour portion that borders the outer edge of the squeezing region. The absorbent article according to claim 4 or 5, wherein a plurality of the high-pressure squeezing portions are arranged in an island shape in the low-pressure squeezing portion. The absorbent article according to any one of claims 1 to 6, wherein the non-squeezed region includes a center point of the upright restraining portion in the vertical direction and the horizontal direction. The absorbent article is arranged between the main body pressing groove and the standing restraining portion, extends laterally and is convex rearward, and neither the front end portion nor the rear end portion is arranged on the vertical groove portion. The absorbent article according to any one of claims 1 to 7, further comprising a linear rearward squeeze groove.

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